BESSEY® Tools North America PV, PVH, SV & SVH Induction Heaters

Total Page:16

File Type:pdf, Size:1020Kb

BESSEY® Tools North America PV, PVH, SV & SVH Induction Heaters BESSEY® Product Training BESSEY® Tools North America PV, PVH, SV & SVH Induction Heaters Page 1-1 Bearing Heater Basics Correct mounting and dismounting tools and methods help to prevent damage to a bearing/part or other machine parts. 60% of premature bearing failure is caused by: incorrect mounting, lack of lubrication, contamination, overdue maintenance . For a maximum bearing lifecycle use correct mounting tools and methods . Machines must be aligned . Correct lubrication is completed . Planned bearing maintenance prevents machine downtime during production runs Page 1-2 Bearing Heater Basics FOR MOUNTING ADVANTAGES: TRANSMISSION PARTS: . Safe . Bearings . Fast . Gear wheels . Clean (environmentally friendly) . Bushes . Microprocessor controlled . Couplings . Energy efficient . Inner rings . Automatic demagnetization . Retains original pre-lubrication . Large choice of standard models Page 1-3 Bearing Heater Basics CORRECT MOUNTING EXTENDS BEARING LIFE BEARING SUPPLIERS ADVISE SHRINK FITTING INDUCTION HEATING IS A SUPERIOR HEATING METHOD . Compared to traditional heating methods, induction heating is a safe and environmentally friendly alternative for ovens, oil baths or blow torches. These methods cause smoke, fumes or oil waste and are hazardous for personal health and safety. Page 1-4 Bearing Heater Basics HOW DOES IT WORK? The heater works by inducing a (low frequency) current in the part to be heated. This is achieved by incorporating the component as a secondary winding in a transformer. The primary winding is connected to the main power by means of an electronic control. The magnetic field induces a high current (short circuit current) through the component which consequently becomes hot. The part is automatically demagnetized after each heating cycle. Page 1-5 Induction Heaters Induction Models: PV2412 . 120 V/15 A, digital control . Max bearing weight 44 lbs . Time to heat 18 kg (39.6 lbs) = 30.0 minutes PVH3813 (Fast Acting) . 120 V/15 A , digital control . Max bearing weight 110 lbs . Time to heat 18 kg (39.6 lbs) = 3.5 minutes . Time to heat 50 kg (110 lbs) = 23.0 minutes SVH5223 (Fast Acting) . 120 V/15 A , digital control . Max bearing weight 330 lbs . Time to heat 50 kg (110 lbs) = 6.0 minutes . Time to heat 65.5 kg (144.1 lbs) = 19.2 minutes . Time to heat 147 kg (323.4 lbs) = 47.0 minutes Page 1-6 Induction Heaters Induction Models: SV5020 • 500 V/16 A, digital control • Max bearing weight 330 lbs SVH7931 (Fast Acting) • 500 V/16 A , digital control • Max bearing weight 770 lbs • Mobile version available Page 1-7 Induction Heaters Fast Acting Models Low energy consumption combined with high output. The coil is positioned differently on specific models to give real-world benefits. Only works for bearings positioned horizontally Page 1-8 Induction Heaters Page 1-9 Induction Heaters Page 1-10 Induction Heater Page 1-11 Induction Heaters Page 1-12 Induction Heaters Page 1-13 NEW Induction Heaters 2016 These units can mount vertically or horizontally so the technical data shows both Page 1-14 CONE HEATER Cone Heater Models: GCS-NCB . Without control setting GCS-CB . With control setting Basic Information: • 120 V/15 A • 10 mm – 203 mm (5/8 – 8 IN) • CE, UL and CSA certified • Produced within an ISO certified facility • European production facility Page 1-15 Thank you for your attention! BESSEY® Tools North America Page 1-16.
Recommended publications
  • Analysis and Optimal Design of Induction Heating Cookers
    J Electr Eng Technol.2016; 11(5): 1282-1288 ISSN(Print) 1975-0102 http://dx.doi.org/10.5370/JEET.2016.11.5.1282 ISSN(Online) 2093-7423 Analysis and Optimal Design of Induction Heating Cookers Muhammad Humza* and Byungtaek Kim† Abstract – This paper deals with the optimal design of induction heating cooker starting from the analytical analysis of the cooker model. The analytical analysis method is based on the construction of the equivalent circuit of the cooker in which the circuit parameters are calculated from the geometries in a very simple way. By using the analysis method of equivalent circuit, the numerous combinations of primary winding coils for the specific rated power are obtained in fast computation time for a given secondary conductor. Through the calculation procedures, the optimal number of turns and their optimal positions can be obtained with which the cooker provides the highest efficiency at the rated power. The effectiveness and accuracy of the proposed analysis and design are verified through finite element analysis for practical and designed models. Keywords: Analysis of induction cooker, Equivalent circuit, Optimal design of primary coil 1. Introduction frequency. The self and mutual inductances of these elements are calculated by using the classical formulas Traditional ways of cooking are hanging the pot on fire obtained from the Biot-Savart law. The concrete equivalent which is produced by burning of wood, coal or gas. These circuit is constructed with the obtained parameters for the traditional ways have a lot of draw backs. The gas burner both primary and secondary windings. By solving the transfer only 35 % to 40 % heat to the pan, which means complicated coupled voltage circuit, a simplified equivalent large portion of heat is wasted and these methods of circuit is obtained.
    [Show full text]
  • Induction Heating Principles PRESENTATION
    Induction Heating Principles PRESENTATION www.ceia-power.com This document is property of CEIA which reserves all rights. Total or partial copying, modification and translation is forbidden FC040K0068V1000UK Main Applications of Induction Heating ¾ Hard (Silver) Brazing ¾ Tin Soldering ¾ Heat Treatment (Hardening, Annealing, Tempering, …) ¾ Melting Applications (ferrous and non ferrous metal) ¾ Forging This document is property of CEIA which reserves all rights. Total or partial copying, modification and translation is forbidden FC040K0068V1000UK Examples of induction heating applications This document is property of CEIA which reserves all rights. Total or partial copying, modification and translation is forbidden FC040K0068V1000UK Advantages of Induction Reduced Heating Time Localized Heating Efficient Energy Consumption Heating Process Controllable and Repeatable Improved Product Quality Safety for User Improving of the working condition This document is property of CEIA which reserves all rights. Total or partial copying, modification and translation is forbidden FC040K0068V1000UK Basics of Induction INDUCTIVE HEATING is based on the supply of energy by means of electromagnetic induction. A coil, suitably dimensioned, placed close to the metal parts to be heated, conducting high or medium frequency alternated current, induces on the work piece currents (eddy currents) whose intensity can be controlled and modulated. This document is property of CEIA which reserves all rights. Total or partial copying, modification and translation is forbidden FC040K0068V1000UK Basics of induction The heating occurs without physical contact, it involves only the metal parts to be treated and it is characterized by a high efficiency transfer without loss of heat. The depth of penetration of the generated currents is directly correlated to the working frequency of the generator used; higher it is, much more the induced currents concentrate on the surface.
    [Show full text]
  • Design Method of an Optimal Induction Heater Capacitance for Maximum Power Dissipation and Minimum Power Loss Caused by Esr
    DESIGN METHOD OF AN OPTIMAL INDUCTION HEATER CAPACITANCE FOR MAXIMUM POWER DISSIPATION AND MINIMUM POWER LOSS CAUSED BY ESR Jung-gi Lee, Sun-kyoung Lim, Kwang-hee Nam ¤ and Dong-ik Choi ¤¤ ¤ Department of Electrical Engineering, POSTECH University, Hyoja San-31, Pohang, 790-784 Republic of Korea. Tel:(82)54-279-2218, Fax:(82)54-279-5699, E-mail:[email protected] ¤¤ POSCO Gwangyang Works, 700, Gumho-dong, Gwangyang-si, Jeonnam, 541-711, Korea. Abstract: In the design of a parallel resonant induction heating system, choosing a proper capacitance for the resonant circuit is quite important. The capacitance a®ects the resonant frequency, output power, Q-factor, heating e±ciency and power factor. In this paper, the important role of equivalent series resistance (ESR) in the choice of capacitance is recognized. Without the e®ort of reducing temperature rise of the capacitor, the life time of capacitor tends to decrease rapidly. This paper, therefore, presents a method of ¯nding an optimal value of the capacitor under voltage constraint for maximizing the output power of an induction heater, while minimizing the power loss of the capacitor at the same time. Based on the equivalent circuit model of an induction heating system, the output power, and the capacitor losses are calculated. The voltage constraint comes from the voltage ratings of the capacitor bank and the switching devices of the inverter. The e®ectiveness of the proposed method is veri¯ed by simulations and experiments. Keywords: Induction heating, Equivalent series resistance, Design 1. INTRODUCTION four thyristors and a parallel resonant circuit com- prised capacitor bank and heating coil.
    [Show full text]
  • ZVS Power Resonator CRO-SM1 Ultra Compact Self Resonating Power Oscillator Features and Specifications
    RMCybernetics CRO-SM1 www.rmcybernetics.com ZVS Power Resonator CRO-SM1 Ultra Compact Self Resonating Power Oscillator Features and Specifications Automatic Resonance, no tuning needed Wide supply voltage range (12V – 30V) ZVS (Zero Voltage Switching) Current up to 10A continuous*, 70A peak Over Voltage, Current, & Temperature Protection Optional modulation input Flat base for mounting directly to metal enclosures** High quality double layer PTH, 2oz Copper PCB Ultra-compact size: L50 x W50 x H8*** mm * Max current varies with operating frequency. ** Electrical isolation required using thermal interface material *** Excluding Heatsink. The CRO-SM1 is a type of collector resonance oscillator circuit which will automatically drive low impedance reactive circuits at their resonant frequency. This is ideal for making a DIY Induction Heater or Solid State Tesla Coil. It is designed to drive a parallel LC circuit (a coil and capacitor connected in parallel). It can be connected in numerous configurations and is also able to work with loads that have a centre tapped coil. The circuit will automatically drive at resonance even if the resonant frequency changes such as when a metal object is placed inside an induction heater. The circuit is designed to work with a wide range of parallel LC (inductor capacitor) circuits which have a relatively low inductance and a large capacitance. For example an induction heater with a few turns on the coil and a large capacitor bank. While this circuit has been designed to be as versatile as possible, there may be certain LC combinations that will not be driven to resonance by the circuit.
    [Show full text]
  • Handbook of Induction Heating Theoretical Background
    This article was downloaded by: 10.3.98.104 On: 28 Sep 2021 Access details: subscription number Publisher: CRC Press Informa Ltd Registered in England and Wales Registered Number: 1072954 Registered office: 5 Howick Place, London SW1P 1WG, UK Handbook of Induction Heating Valery Rudnev, Don Loveless, Raymond L. Cook Theoretical Background Publication details https://www.routledgehandbooks.com/doi/10.1201/9781315117485-3 Valery Rudnev, Don Loveless, Raymond L. Cook Published online on: 11 Jul 2017 How to cite :- Valery Rudnev, Don Loveless, Raymond L. Cook. 11 Jul 2017, Theoretical Background from: Handbook of Induction Heating CRC Press Accessed on: 28 Sep 2021 https://www.routledgehandbooks.com/doi/10.1201/9781315117485-3 PLEASE SCROLL DOWN FOR DOCUMENT Full terms and conditions of use: https://www.routledgehandbooks.com/legal-notices/terms This Document PDF may be used for research, teaching and private study purposes. Any substantial or systematic reproductions, re-distribution, re-selling, loan or sub-licensing, systematic supply or distribution in any form to anyone is expressly forbidden. The publisher does not give any warranty express or implied or make any representation that the contents will be complete or accurate or up to date. The publisher shall not be liable for an loss, actions, claims, proceedings, demand or costs or damages whatsoever or howsoever caused arising directly or indirectly in connection with or arising out of the use of this material. 3 Theoretical Background Induction heating (IH) is a multiphysical phenomenon comprising a complex interac- tion of electromagnetic, heat transfer, metallurgical phenomena, and circuit analysis that are tightly interrelated and highly nonlinear because the physical properties of materi- als depend on magnetic field intensity, temperature, and microstructure.
    [Show full text]
  • Closed Loop Controlled AC-AC Converter for Induction Heating by Mr
    Volume 25, Number 2 - April 2009 through June 2009 Closed Loop Controlled AC-AC Converter for Induction Heating By Mr. D. Kirubakaran & Dr. S. Rama Reddy Peer-Refereed Article Applied Papers KEYWORD SEARCH Electricity Electronics The Official Electronic Publication of the The Association of Technology, Management, and Applied Engineering • www.nait.org © 2009 Journal of Industrial Technology • Volume 25, Number 2 • April 2009 through June 2009 • www.nait.org Closed Loop Controlled AC-AC Converter for Induction Heating By Mr. D. Kirubakaran & Dr. S. Rama Reddy Abstract the inverting circuit is constructed by A single-switch parallel resonant con- traditional mode with four controlled verter for induction heating is simu- switches. The above literature does not Mr. D.Kirubakaran has obtained M.E. degree lated and implemented. The circuit con- deal with closed loop modeling and from Bharathidasan University in 2000. He is sists of input LC-filter, bridge rectifier embedded implementation of AC to presently doing his research in the area of AC- AC converter fed induction heater. In AC converters for induction heating. He has 10 and one controlled power switch. The years of teaching experience. He is a life member switch operates in soft commutation the present work AC to AC converter is of ISTE. mode and serves as a high frequency modeled and it is implemented using generator. Output power is controlled an atmel microcontroller. The present via switching frequency. Steady state problem aims to minimize the cost of analysis of the converter operation induction heater system by using an is presented.. A closed loop circuit embedded controller.
    [Show full text]
  • Induction Heating Applications the Processes, the Equipment, the Benefits CONTENTS
    Induction heating applications The processes, the equipment, the benefits CONTENTS Introduction ..........................................................................3 Forging .................................................................................14 Induction coils ................................................................ 4-5 Melting .................................................................................15 Hardening ..............................................................................6 Straightening .....................................................................16 Tempering ..............................................................................7 Specialist applications ..................................................17 Brazing ....................................................................................8 How induction works .................................................................... 19 Bonding ..................................................................................9 Selecting the best solution ......................................... 20-21 Welding ................................................................................10 International certifications .................................................... 22 Annealing / normalizing ................................................................11 Some of our customers..................................................................23 Pre-heating ........................................................................12
    [Show full text]
  • Induction Heater for Automotive Applications
    (19) TZZ Z¥4A_T (11) EP 2 608 634 A1 (12) EUROPEAN PATENT APPLICATION (43) Date of publication: (51) Int Cl.: 26.06.2013 Bulletin 2013/26 H05B 6/10 (2006.01) (21) Application number: 11195710.6 (22) Date of filing: 23.12.2011 (84) Designated Contracting States: (72) Inventor: Kaman, Richard AL AT BE BG CH CY CZ DE DK EE ES FI FR GB Spring Grove, IL 60081 (US) GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR (74) Representative: Casey, Lindsay Joseph Designated Extension States: FRKelly BA ME 27 Clyde Road Ballsbridge (71) Applicant: Induction Holding Company, LLC Dublin 4 (IE) Elgin, IL 30123-2595 (US) (54) Induction heater for automotive applications (57) A heater apparatus 10 used for automotive re- hysteretic circuit and a plurality of hand-held, manipula- pair, which may be powered by a 240-volt AC power ble applicators 18, which may be functionally engaged source, and which may utilize a frequency in a range of to the circuit for use in applying heat generated by the 15-50 KHz. Apparatus 10 may include an eddy current/ circuit to desired areas of automotive vehicles. EP 2 608 634 A1 Printed by Jouve, 75001 PARIS (FR) 1 EP 2 608 634 A1 2 Description methods. [0007] In general, those of ordinary skill in the art will BACKGROUND OF THE INVENTION appreciate that, with respect to the heater apparatus de- scribed in U.S. Patent Nos. 6,563,096 and 6,670,590, [0001] The present invention generally relates to in- 5 the transformer "turns-ratio" was redesigned to account duction heaters used for removing fasteners and other for the higher input voltage while keeping the output volt- automotive repair applications requiring the release of age the same, and that the C3 value was changed to hardware from corrosion/thread lock compounds, or in- keep the LC resonance at the same frequency.
    [Show full text]
  • A Microprocessor-Based Control, Scheme for a Pwm Voltage-Fed Inverter with an Induction Heating Tank Load
    Nigerian Journal of Technology, Vol. 23, No. 1, March 2004 Agu 1 A MICROPROCESSOR-BASED CONTROL, SCHEME FOR A PWM VOLTAGE-FED INVERTER WITH AN INDUCTION HEATING TANK LOAD Marcel U. Agu, Department of Electrical Engineering University of Nigeria, Nsukka ABSTRACT In this paper, the flexibility of programmed control logic is exploited in the close loop control of a PWM thyristor voltage fed inverter supplying an induction heating tank load. The microprocessor used in the control is the MC6809 to which is interfaced the SY6522 versatile interface adapter (VIA). The microprocessor-based scheme performs the dual function of generating the thyristor gating signals as well as estimating and applying control actions to maintain the load power factor at unity and the power delivered to the load at a desired set-point value. The schemed also provides power circuit over-current and over-voltage protection against adverse changes in the inverter input supply and the load. The estimation of the control variables of the control scheme proportional plus integral controllers constitute the main control program while the application of thyristor gating signals and closed loop control actions are carried out in response to interrupts external to the microprocessor unit. Illustrative steady state and transient circuit of an experimental model of the induction heater are given. to a parallel capacitor compensated induction 1. INTRODUTION heating load is evident. Induction heating of metals is widely used in This paper presents an MC6809 the industry for melting, casting, forging, microprocessor based closed loop control of annealing and /or hardening work. In majority an induction heater comprising of a single of the medium power induction heating pulse per half cycle modulated voltage fed applications, the static power supply is the inverter with a parallel capacitor compensated load commutated current source inverter (CSI) induction load.
    [Show full text]
  • IGBT Induction Heater Profiles
    IGBT Induction Heater Profiles United Induction Heating Machine Limited UIHM is experienced in Induction Heating Machine and Induction Heating Power Supply,induction heating equipments can be used in induction heating service, induction heat treatment, induction brazing, induction hardening,induction welding, induction forging,induction quenching,induction soldering induction melting and induction surface treatment applications http://www.uihm.com MF IGBT power transistor module is in the early 1990s, foreign advanced technology, developed a new type of variable frequency induction heating equipment, won the “National New Product Award”. Wide range of applied high-capacity, high efficiency melting occasion, and through high-frequency Induction heated machine, heat treatment and other heating applications. IGBT induction heating power supply, as a constant power output of power supply, Inverter part series resonance, using advanced IGBT transistor devices. The new power supply in many ways superior to the performance of SCR frequency power supply, is the old type KGPS-Series SCR frequency furnace replacements. Mainly used in smelting ordinary carbon steel, stainless steel, can be used for smelting copper, aluminum and other nonferrous metals, can also be used to melt silicon, polysilicon and other non-metallic. With high efficiency, rapid melting of the advantages of burning metal element less, less slag, liquid steel quality is good. Improve the casting quality, and yield, reduce production costs. Second, the product advantages: 1, IGBT frequency power supply as a constant power output of power, some for the use of series resonant inverter and inverter voltage is high, all the IGBT IF frequency energy than the average SCR; IGBT transfer power FM frequency used, some with full-bridge rectifier rectifier, inductor and capacitor filter, and has been working on 500V, so the frequency IGBT high harmonic generation of small, low industrial pollution on the grid.
    [Show full text]
  • Induction Bearing Heaters User Manual
    Induction Bearing Heaters User Manual SC110D, SC110V, BC and BCS models READ THE MANUAL AND SAFETY INSTRUCTIONS Check all parts for possible transport damage. If any damage is apparent, inform carrier immediately. besseytools.com TABLE OF CONTENTS 1. Safety Instructions ....................................................................................................................... 2 2. Application ....................................................................................................................................... 3 2.1 SC110V, BC and BCS Models 2.2 SC110D Model 2.3 Bearing heater operating conditions 2.4 Principle of Operation 3. Installation ........................................................................................................................................ 6 4. Cleaning and Maintenance ................................................................................................... 7 5. Pyrometer ........................................................................................................................................... 7 1. Safety Instructions WARNING! These indicate potential risk of serious personal injury CAUTION! These indicate danger of damaging the heater or workpiece WARNING! ■ Induction heaters generate a magnetic induction field, which may affect or impair medical devices such as pacemakers or hearing aids, resulting in a high risk of serious bodily harm. Do not operate, or be within a suggested minimum distance of 5m (16ft) of the machine while wearing such devices.
    [Show full text]
  • Analysis of a Full-Bridge Direct Ac-Ac Boost Converter Based Domestic Induction Heater
    Rev. Roum. Sci. Techn.– Électrotechn. et Énerg. Vol. 64, 3, pp. 223–228, Bucarest, 2019 ANALYSIS OF A FULL-BRIDGE DIRECT AC-AC BOOST CONVERTER BASED DOMESTIC INDUCTION HEATER AVIJIT CHAKRABORTY1, ARIJIT CHAKRABARTI2, PRADIP KUMAR SADHU2 Key words: Induction heating, Insulated gate bipolar transistor, Switching loss, Duty cycle, Zero-voltage switching (ZVS). Induction heating is now gradually emerging as a very reliable technology for providing faster heating in domestic and various industrial applications. It finds profound acceptability in the appliances like domestic induction cookers regarding its advantages of very fast heating, efficiency, accurate power and temperature control. Any induction heating system requires three major components, a high frequency power converter, resonant tank circuit and control circuit respectively. Recently, new research trends in the field of domestic induction heating pursue the design and implementation of new bridgeless topologies to make efficient and cost-effective domestic induction heaters. In this paper, a highly efficient direct ac-ac boost converter based induction heater is proposed employing a full-bridge series resonant inverter (FB-SRI) with insulated gate bipolar transistor (IGBT) as the power electronic switch. Power requirement of the induction heater is continuously regulated using a closed loop control system. The proposed inverter incorporates a voltage boost control technique using only two diodes for rectification of the main supply voltage. After maintaining proper sequence of firing the IGBTs, the converter can operate with zero-voltage switching (ZVS) during both switch-on and switch-off conditions. The performance of the proposed induction heating system is later compared with a conventional full-bridge (FB) series resonant inverter (SRI) based induction heater.
    [Show full text]